The present invention pertains to devices and methods for sharpening scissors, in particular scissors designed for personal hair cutting. Hair scissors, or shears as they are often called, are precise instruments that require careful periodic sharpening to provide quality performance. The cutting surfaces of such scissors may be flat but are more commonly curved in more than one direction to optimize cutting with a minimum of force and drag on the hair. In particular, it is popular for scissor blades to be curved, from root of the cutting surface near the handle to the tip. Blades with an 600 to 1000 millimeter blade shape radius are very popular and are used on many of the best scissors for hair cutting. Similarly, the scissor cutting surface is often convex shaped. The result, in a scissors with a radius and convex shape, is a complex cutting surface.
When scissors blades are sharpened, it is critical that the existing shape of the cutting surfaces be maintained. This is relatively simple for scissors with straight and flat blades, but this requirement is very difficult to meet with blades with complex blade surfaces such as found on a scissors with both a blade radius and convex face. Available sharpening devices have flat working surfaces. To properly sharpen a complex curved scissors blade with a flat sharpening device requires very precise and complicated movements. In many instances, improper sharpening results in flats or irregularities in the scissors shape and cutting surfaces and, effectively, a destroyed scissors blade.
There are prior art devices that attempt to provide accurate sharpening of curved scissor blades. For example, U.S. Pat. No. 7,118,466 to Laney provides a curved guide bar to attempt to limit the movement of a clamped scissor blade to a single preselected shape. However, at best, the Laney device is still dependent on proper user operation and without careful operation a blade can be ruined during sharpening. Also, due to the limitations of the Laney guide bar, it is difficult to sharpen any blade—such as a previously improperly sharpened blade—that deviates from the predefined shape.
There remains a demand for a scissors sharpening device that reduces the difficulty in sharpening curved scissor blades. Preferably, such a device will allow for sharpening blades with irregularities such as variable blade radius that have been produced from prior improper sharpening and that will duplicate the many flat and curved blades manufactured.
The present invention is a device, system and method for sharpening straight, curved and irregular shaped scissors blades. A generally flat sharpening surface is used, such as a conventional motor-driven rotating sharpening pad. A moving frame and blade holder or mount are provided to retain a scissors blade in preselected orientation to the sharpening pad. The frame provides independent linear horizontal and vertical movement to the blade mount that allows a mounted blade to be moved over and downward through the plane of the pad.
The blade holder also has a pivot providing a circular movement range about a pivot rotation axis that is parallel to, and above, the sharpening pad. The blade holder includes a blade retaining surface oriented such that a blade may be retained generally parallel to the rotation axis of the blade holder. The pivot and circular movement range provides for addressing any convex blade surface.
In inventive methods of sharpening, a scissors blade is retained in the blade holder of the device such that the blade may be moved into and below the horizontal plane of a sharpening pad. The long axis of the blade is angled with respect to the plane of the pad such that the blade surface can intersect and bear on a small flexible perimeter region of the pad. The blade surface is moved transversely, in a radially outward direction, over the perimeter region with a continuous uniform stroke. During this stroke a uniform downward pressure is exerted on the blade, through the blade holder, sufficient to force and retain a bend in the perimeter region and create a pad sharpening region parallel to the blade surface. To maintain this orientation during the outward stroke, the blade holder is moved linearly downward and, simultaneously and independently, linearly outward. Limits are provided to prevent horizontal movements of the blade holder that might damage the scissored blade.
In a preferred method step, the blade holder is rotated about its pivot while the held scissor blade surface is in contact with the sharpening pad to form a convex shape on the blade surface. This is repeated in a step-wise fashion as the blade moves over a transverse path over the pad perimeter to complete the convex shape over the entire length of the blade.
The invention includes a system for sharpening scissors blades that includes an integrated rotating sharpening pad, or may form an independent frame and holder for use with separate or attached conventional rotating sharpening pad devices.
Due to the high rate of use and sharpening of professional hair cutting scissors, their initial shapes are often altered. This makes more problematic effective sharpening. Scissor blade surfaces may have uneven shapes such as flats in curved surfaces. This fact makes many of the prior sharpening devices and methods ineffective in many situations. In particular, where sharpening is performed against a broad flat surface larger than the scissor blade, concave blades surfaces cannot be addressed. Prior methods that limit the scissor blade movement path during sharpening also suffer from an ability to adapt to any irregularity in blade shape. The present device and method enable sharpening of any of these blade shapes.
Additional novel aspects and benefits of the invention Will be discerned from the following description of particular embodiments and the accompanying figures.
a and 3b are front views of a scissor blade oriented in two positions respecting a sharpening pad in the inventive methods. For clarity, the inventive blade holder is not shown.
In
The vertical rail 20 and horizontal rail 22 structures are shown schematically and their constructions may take any of a variety of alternative forms providing the same required functions and operations defined herein. Examples are conventional linear guide rails. Two perpendicular linear guide rails may be joined to provide the necessary structure and operation. In such a case, the base 14 would be slidably coupled to, or integral with, the moving platform of the vertical guide rail.
Together the vertical rail 20 and horizontal rail 22 are here named, for convenience, a movement “frame” 30. A critical feature of the frame 30 is the independence of vertical and horizontal movement provided to the blade mount 12 through the base 14. To clarify this independence requirement, vertical and horizontal movement of the blade mount 12 must be independent from each other at all points. This is necessary to enable addressing the infinitely variable blade shapes that exist in scissor blades in use at any time. The horizontal rail 22 includes two limiting stops 24 that define the extremes of horizontal movement of the device. The application of these stops 24 will be discussed below.
The grip 13 is secured to the base 14 through a pivot pin 26 that enables the grip 13 to pivot, relative to the base 14, about a horizontal pivot axis 28. It is critical that the pivot axis 28 be parallel to the axis of movement of the horizontal rail 22. At the distal end of the grip 13, a scissor blade mounting surface 40 and a clamp 41 form a blade mounting fixture for securing a blade 90 in the proper orientation for sharpening according to the inventive methods. The mounting surface 40 is preferably flat and parallel to the pivot axis 28, such that the pivot axis lies on the plane of the mounting surface 40. This flat construction will match the shape of most scissor blades in use today. However, the mounting surface 40 may, alternatively, be shaped to accommodate non-flat scissor blades so long as the effective result is that the blade 90 is secure in a plane including the pivot axis 28, as mentioned. This orientation is necessary to enable the proper movement of the blade 90 relative to a horizontal sharpening surface to produce a convex blade surface as discussed below. The clamp 41 is shown in the form of a threaded shaft with a manually operable turn knob and clamp face that secures the blade 90 against the mounting surface 40. Other clamping devices and methods may be likewise employed for the same result. In any case, it is critical that, in use, the blade be held rigid against the mounting surface 40.
It is important to control the angle of the grip 13 relative to the base 14. In the embodiment shown, this is accomplished through a control pin 50 that protrudes perpendicularly (horizontally) from the face of the base 14 and blocks further downward rotation of the grip 13. Upward rotation is limited by gravity, and, during sharpening operations, by the user's manual pressure on the grip 13. The control pin 50 is placed to provide the proper blade surface angle TH of the blade cutting surface 91 to the pad horizontal sharpening surface. A nominal blade angle of 40 to 80 degrees is found in many conventional hair cutting scissor blades. Various different angles may be enabled by providing several control pin holes 52 in which the control pin 50 may be, alternatively, placed. It is convenient to provide holes for increments of 5 degrees in blade angle TH. Other devices and means of limiting the range of the rotation of the grip 13 may be used as alternatives to the control pin 50 for the same function.
Sharpening of a scissor blade is accomplished by using a rotating (spinning) horizontal face pad 60. Preferably the pad is driven by an electric motor housed in a cabinet with appropriate controls. A conventional motor-driven flat hone may be used if the sharpening surface may be replaced. Many such hones have magnetic mounting disks on which the sharpening pad may be removably secured by magnetic attraction to the mounting disk 62. It is important that the center portion of the pad 60, or the mounting disk, be generally rigid. The pad 60 has a flat sharpening face surface 61 with an appropriate sharpening medium, such as aluminum oxide. Diamond grit may be used but is often too aggressive and tends to load up with metal. Various different pads with progressively finer grit may be used as in conventional sharpening methods. A finish pad with the equivalent of 1200 to 3000 grit is suggested for hair cutting scissors. Very fine diamond grit such as about three micron or smaller may be useful for polishing.
The sharpening pad is oriented with a horizontal pad plane 68 as shown in the figures. In the embodiment shown in the figures, the pad 60 consists of a somewhat flexible sheet that is mounted to a rigid metal supporting mounting disk 62. The pad 60 is larger in diameter than the mounting disk 62 such that an overhang portion 63 of the pad that results has no underlying support. The necessary radial dimension of the overhang portion 63 is dependent on the thickness and flexibility of the pad 60.
To enable the required flexing of the pad perimeter portion 64, the overhang portion 63 must be flexible. Conventional pads are formed of a variety of different materials including rigid metals with diamond grit surfaces. Such rigid pads cannot be used as they will not provide a flexed perimeter portion. Similarly, less rigid materials such as rubber or plastics will be unsuitable if too thick or the overhand too short. Rigid pads are incapable of providing a sharpening surface angled from the horizontal pad plane 68 as the flexed perimeter portion 64 provides in the invention. A rigid pad will provide only one-dimensional line bearing to an angled incident blade, likely destroying the blade in any attempted sharpening action. Note that conventional pads, including flexible pads, typically have uniform thickness and material properties, and therefore references herein to pad properties do not distinguish perimeter portion properties, however it should be understood that the critical properties are those of the perimeter portion 64.
During testing of a prototype, for a plastic pad having a thickness of 0.0017 inches, an overhang dimension RD of 0.063 inches was sufficient to provide an acceptably flexible pad perimeter region. A lesser radial overhand is not suggested as providing insufficient bearing surface for most pads. In the above prototype the ratio of overhand dimension RD to pad thickness is approximately 3.6. This is a suggested guide for acceptable overhand dimension RD for flexible pads of different thicknesses. This applies to pad materials of similar acceptable flexibility such as rubber and leather, both of which may be used.
Examples of the inventive methods of sharpening will now be detailed during which the critical performance of the pad 60 will be explained. A long axis 70 of a scissor blade 90 is defined here as a line passing through the center of the blade 90 and parallel a line through the cutting surface tip 92 and root. Generally, during the inventive sharpening process, a scissor blade is held with the long axis 70 angled with respect to the pad plane 68 as shown in
The above interaction of the blade 90 and pad 60 must only occur while both: the pad 60 is rotating at an effective speed for sharpening, and also the blade 90 is moving transversely outward. If at any time the blade 90 is stationary, a deleterious flat irregularity will be cut by the pad on the blade surface 91. Due to the angular orientation of the blade 90 respecting the pad, in order to maintain contact between the blade 90 and the pad 60, the blade 90 must be moved vertically downward at the same time as it is moved transversely outward as illustrated by the movement arrows in
The above described “outward” movement of the blade 90 is radial if the blade long axis 70 passes through the vertical centerline of rotation of the pad 60. The blade may located slightly off-center from this radial orientation during sharpening and still effect the same result. In such cases, the transverse movement is not quite radial. However, as long as the movement of the pad perimeter portion 64 is consistent and approximately perpendicularly across the blade surface 91, the inventive methods may be successfully carried out.
When sharpening blades that have a radius or are otherwise non-straight, as the blade 90 is moved outward, the blade angle BH between the pad plane 68 and the blade surface 91 at the point of contact will change. In many circumstances, this angle may be practically unknownable due to random irregularities formed in the blade during prior sharpenings, as discussed above. However, a unique benefit of the current method is that the flexing pad perimeter portion 64 accommodates these blade surface angular changes to provide a sharpening effect substantially equal over the entire blade surface 91, regardless of angle changes. In
However, in the just described method, to allow the blade 90 to be maintained in contact with the perimeter portion 64 it is also necessary that the vertical and horizontal movements of the blade 90 be independent as the relationship between them is unknowable in the same manner as the angle BH. For this reason, the operation of the vertical rail 20 must be independent of the horizontal rail 22. Constructions that proscribe or limit the range or relationship of the two axes of motion will be unable to accommodate irregular blade shapes and therefore are contrary to the present invention.
In a preferred method, a blade is fixed in the grip 63 as shown in the figures. The mount 12 is then manipulated by the user to locate the blade 90 with the root of the blade surface 91 vertically above and separated from the perimeter portion 64. In a single continuous motion, the mount 12 is moved simultaneously downward and outward, to push the blade 90 against the pad, flexing the perimeter portion 64, and drawing the entire length of the surface 91 over the flexed perimeter portion 64. The mount 12 and blade 90 are raised from the pad when the tip 92 of the blade reaches the perimeter portion 64. This movement of the blade 90 should be substantially with consistent speed and pressure. It is critical that movement of the blade not continue to allow the tip 92 to impinge the edge of the pad 60.
Depending on the amount of metal that must be removed to sufficiently sharpen a blade, the above step may be repeated. By using a fine grit pad and light pressure, sharpening may be accomplished using multiple passes without removing too much metal. Multiple passes will reduce the effect of any inconsistencies in movement speed and pressure.
As illustrated in
Optionally, a convex blade surface may be also shaped or reshaped by the following steps. Herein and typically, “convex” refers to the surface shape in a plane perpendicular to the long axis 70. Preferably after the blade has been sharpened along its long axis as described above, the blade grip 13 is rotated (upward) about its pivot 26 while a clamped scissor blade surface is in contact with the sharpening pad 60 to form a convex shape on the blade surface. This is repeated in a step-wise fashion as the blade 90 repeats its transverse path over the pad perimeter to complete the convex shape over the entire length of the blade 90. A specific rotation angle is somewhat dependent on the existing convex shape of the particular blade, but generally rotating the grip 13 through an angle of 10 to 15 degrees while maintaining a light pressure on the pad 60 will be effective. To maintain blade contact with the pad 60, the mount 12 must be moved downward without horizontal movement. Multiple passes may be necessary and this may be determined by examination by a generally skilled user at the time.
The embodiment of the figures is configured for sharpening right-hand scissor blades. However, the same device may be used for left-hand scissors by altering the relative placement of the pad 60 (and rotation) and reversing the orientation of the blade 90 in the mount grip 13. The particular vertical location of the horizontal rail 22 is not critical and may be above or below the pad 60 so long as the described location and movement of the mount 12 is provided.
The elements of the mount 12 may be formed of structural metals or other alternative materials having similar properties. The structural elements of the base 14 may be integrated into the vertical rail 20 so long as the defined movements of the mount 12 are provided.
For convenience, the inventive device may include an enclosure or housing including an integrated sharpening device including a replaceable pad 60. Alternatively, the inventive device may be configured to accept a conventional sharpening hone with an appropriate horizontal pad. In such a case, the enclosure or other integrating structure must provide for proper orientation of the hone with the frame 30. The invention includes using conventional sharpening hones by their application with structures as described above to enable the inventive methods.
The preceding discussion is provided for example only. Other variations of the claimed inventive concepts will be obvious to those skilled in the art. Adaptation or incorporation of known alternative devices and materials, present and future is also contemplated. The intended scope of the invention is defined by the following claims.
Number | Name | Date | Kind |
---|---|---|---|
1958021 | Schmidt | May 1934 | A |
4984391 | Sattler | Jan 1991 | A |
5157870 | Pike | Oct 1992 | A |
5291690 | Pike | Mar 1994 | A |
5624304 | Pasch et al. | Apr 1997 | A |
7118466 | Laney | Oct 2006 | B2 |
7959494 | Pietrzak | Jun 2011 | B1 |
20080020681 | Leyva | Jan 2008 | A1 |
Number | Date | Country | |
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20100203810 A1 | Aug 2010 | US |